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Ashish Dikshit
Exploring fluid mechanics using Wolfram notebook
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Syllabus
Project Overview
In this 1-hour long project-based course, you will learn how to Compute pressure with Bernoulli's equation, Compute the buoyancy of different materials in various liquids and gases, Calculate the fluid flow through pipe, Do a Venturi flowmeter computation and calculate Barometric pressure. Fluid mechanics is the branch of physics concerned with the mechanics of fluids (liquids, gases, and plasmas) and the forces on them. The assumptions inherent to a fluid mechanical treatment of a physical system can be expressed in terms of mathematical equations. Fundamentally, every fluid mechanical system is assumed to obey: Conservation of mass, Conservation of energy, Conservation of momentum & the continuum assumption
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possible dealbreakers
Explores fluid mechanics, which is vital for understanding fluids in various industries such as engineering, physics, and aerospace
Taught by Ashish Dikshit, who is highly recognized for his expertise and research in fluid mechanics
Involves hands-on computations and simulations, enhancing practical understanding of fluid mechanics principles
Develops proficiency in fluid mechanics, which is essential for solving real-world engineering problems involving fluids
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Activities
Be better prepared
before
your course. Deepen your understanding
during
and
after
it. Supplement your coursework and achieve mastery of the topics covered
in Exploring fluid mechanics using Wolfram notebook with these
activities:
Organize Course Materials
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Establish a structured system for organizing and reviewing your course materials to enhance retention and retrieval.
Browse courses on
Knowledge Management
Show steps
-
Gather all course materials, including notes, handouts, assignments, and recordings.
-
Categorize and organize the materials by topic or module for easy access.
-
Review the organized materials regularly to reinforce your understanding and identify areas for improvement.
Review Bernoulli's Equation
Show steps
Review the principles of Bernoulli's equation to build a strong foundation for understanding fluid mechanics concepts.
Show steps
-
Revisit the definition and mathematical form of Bernoulli's equation.
-
Analyze solved examples and applications of Bernoulli's equation to fluid flow.
Review 'Fluid Mechanics' by Pijush K. Kundu
Show steps
Expand your understanding of fluid mechanics fundamentals through a comprehensive review of a foundational textbook.
View
Fluid Mechanics
on Amazon
Show steps
-
Read through chapters relevant to the course topics, focusing on key concepts and principles.
-
Summarize important sections and make notes to reinforce your understanding.
-
Solve practice problems and review solved examples to test your comprehension.
Five other activities
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Show all eight activities
Explore Wolfram Notebook Examples
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Navigate through Wolfram Notebook tutorials to enhance your understanding of fluid mechanics simulations and computations.
Browse courses on
Wolfram Notebook
Show steps
-
Identify relevant Wolfram Notebook examples related to fluid mechanics topics.
-
Step through the tutorials, taking notes on the code and concepts.
-
Practice applying the techniques learned in the tutorials to solve fluid mechanics problems.
Join a Study Group
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Collaborate with peers in a study group to reinforce your understanding through discussions and problem-solving.
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Group Discussions
Show steps
-
Connect with classmates or join an existing study group dedicated to fluid mechanics.
-
Schedule regular meetings to discuss course topics, solve problems, and share insights.
-
Actively participate in discussions and contribute your knowledge to the group.
Solve Fluid Mechanics Problems
Show steps
Engage in problem-solving drills to strengthen your comprehension and application of fluid mechanics concepts.
Browse courses on
Problem-Solving
Show steps
-
Source practice problems from textbooks, online resources, or the course materials.
-
Set aside dedicated time for solving the problems, without referring to solutions.
-
Review your solutions against provided answers or consult with the instructor for feedback.
Develop a Fluid Mechanics Glossary
Show steps
Create a comprehensive glossary of fluid mechanics terms to enhance your understanding and retention of key concepts.
Browse courses on
Technical Writing
Show steps
-
Compile a list of essential fluid mechanics terms from course materials and additional sources.
-
Define each term concisely and accurately, using clear and non-technical language.
-
Organize the glossary alphabetically or by topic for easy reference.
Contribute to Fluid Mechanics Open Source Projects
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Engage with the fluid mechanics community by contributing to open-source projects, expanding your knowledge and practical skills.
Browse courses on
Open Source Projects
Show steps
-
Identify open-source fluid mechanics projects aligned with your interests and skill level.
-
Review project documentation and contribute to bug fixes, feature enhancements, or new developments.
-
Collaborate with project maintainers and fellow contributors to enhance the project's functionality and usability.
Organize Course Materials
Show steps
Establish a structured system for organizing and reviewing your course materials to enhance retention and retrieval.
Browse courses on
Knowledge Management
Show steps
Show steps
Show steps
- Gather all course materials, including notes, handouts, assignments, and recordings.
- Categorize and organize the materials by topic or module for easy access.
- Review the organized materials regularly to reinforce your understanding and identify areas for improvement.
Review Bernoulli's Equation
Show steps
Review the principles of Bernoulli's equation to build a strong foundation for understanding fluid mechanics concepts.
Show steps
Show steps
Show steps
- Revisit the definition and mathematical form of Bernoulli's equation.
- Analyze solved examples and applications of Bernoulli's equation to fluid flow.
Review 'Fluid Mechanics' by Pijush K. Kundu
Show steps
Expand your understanding of fluid mechanics fundamentals through a comprehensive review of a foundational textbook.
View
Fluid Mechanics
on Amazon
Show steps
Show steps
Show steps
- Read through chapters relevant to the course topics, focusing on key concepts and principles.
- Summarize important sections and make notes to reinforce your understanding.
- Solve practice problems and review solved examples to test your comprehension.
Five other activities
Expand to see all activities and additional details
Show all eight activities
Explore Wolfram Notebook Examples
Show steps
Navigate through Wolfram Notebook tutorials to enhance your understanding of fluid mechanics simulations and computations.
Browse courses on
Wolfram Notebook
Show steps
Show steps
Show steps
- Identify relevant Wolfram Notebook examples related to fluid mechanics topics.
- Step through the tutorials, taking notes on the code and concepts.
- Practice applying the techniques learned in the tutorials to solve fluid mechanics problems.
Join a Study Group
Show steps
Collaborate with peers in a study group to reinforce your understanding through discussions and problem-solving.
Browse courses on
Group Discussions
Show steps
Show steps
Show steps
- Connect with classmates or join an existing study group dedicated to fluid mechanics.
- Schedule regular meetings to discuss course topics, solve problems, and share insights.
- Actively participate in discussions and contribute your knowledge to the group.
Solve Fluid Mechanics Problems
Show steps
Engage in problem-solving drills to strengthen your comprehension and application of fluid mechanics concepts.
Browse courses on
Problem-Solving
Show steps
Show steps
Show steps
- Source practice problems from textbooks, online resources, or the course materials.
- Set aside dedicated time for solving the problems, without referring to solutions.
- Review your solutions against provided answers or consult with the instructor for feedback.
Develop a Fluid Mechanics Glossary
Show steps
Create a comprehensive glossary of fluid mechanics terms to enhance your understanding and retention of key concepts.
Browse courses on
Technical Writing
Show steps
Show steps
Show steps
- Compile a list of essential fluid mechanics terms from course materials and additional sources.
- Define each term concisely and accurately, using clear and non-technical language.
- Organize the glossary alphabetically or by topic for easy reference.
Contribute to Fluid Mechanics Open Source Projects
Show steps
Engage with the fluid mechanics community by contributing to open-source projects, expanding your knowledge and practical skills.
Browse courses on
Open Source Projects
Show steps
Show steps
Show steps
- Identify open-source fluid mechanics projects aligned with your interests and skill level.
- Review project documentation and contribute to bug fixes, feature enhancements, or new developments.
- Collaborate with project maintainers and fellow contributors to enhance the project's functionality and usability.
Career center
Learners who complete Exploring fluid mechanics using Wolfram notebook will develop knowledge and skills
that may be useful to these careers:
Computational Fluid Dynamics Engineer
Computational Fluid Dynamics Engineer
Computational Fluid Dynamics Engineers research and develop numerical methods to simulate fluid behavior. They work with engineers to apply these methods to design and optimize flow systems. Research and development may require advanced knowledge of modeling, computational mathematics, and high-performance computing, which makes a course in computational fluid mechanics a good fit.
Aerospace Engineer
Aerospace Engineer
Aerospace Engineers design, develop, test, and operate aircraft, spacecraft, and missiles. They apply fluid mechanics principles to solve real-world problems in the field of aerospace engineering, making this course a possible fit.
Petroleum Engineer
Petroleum Engineer
Petroleum Engineers design and operate equipment used to extract oil and gas from the earth. They use fluid mechanics when designing and managing extraction systems, making this course a potential fit.
Mechanical Engineer
Mechanical Engineer
Mechanical Engineers design, develop, and test machines and mechanical systems. They may work with fluids to prevent energy loss within machines and systems, making this course a potential fit.
Civil Engineer
Civil Engineer
Civil Engineers design, build, and maintain infrastructure, such as roads, bridges, and buildings. They apply principles of fluid mechanics when designing irrigation systems, water supply systems, and other systems involving fluid flow, making this course a potential fit.
Chemical Engineer
Chemical Engineer
Chemical Engineers design, build, and operate chemical plants and processes. They use fluid mechanics to design and optimize processes involving the flow of liquids and gases, making this course a potential fit.
Ocean Engineer
Ocean Engineer
Ocean Engineers design, build, and operate structures and systems in the ocean. They may apply fluid mechanics when designing and optimizing systems for marine operations, making this course a potential fit.
Environmental Engineer
Environmental Engineer
Environmental Engineers design, build, and operate systems to control and remediate environmental pollution. They may use fluid mechanics to design and optimize systems for water treatment, air pollution control, and other processes, making this a potential fit.
Naval Architect
Naval Architect
Naval Architects design, build, and maintain ships and other marine vessels. They apply principles of fluid mechanics when designing and optimizing ship hulls, making this course a possible fit.
Hydraulic Engineer
Hydraulic Engineer
Hydraulic Engineers design, build, and maintain hydraulic systems, which are used to control and manage the flow of water. A course in computational fluid mechanics may be useful by helping build a foundation in the principles of fluid flow.
Actuary
Actuary
Actuaries analyze and assess financial risks. They may use fluid mechanics to create mathematical models to analyze and predict the flow of money and other financial assets, making this course a potential fit.
Software Engineer
Software Engineer
Software Engineers design, develop, and maintain software systems. They may use fluid mechanics to simulate and optimize the flow of data in software systems, making this course a potential fit.
Data Scientist
Data Scientist
Data Scientists collect, analyze, and interpret data to help businesses make decisions. They may use fluid mechanics to model and simulate fluid flow in various systems, making this course a potential fit.
Biomedical Engineer
Biomedical Engineer
Biomedical Engineers design and develop medical devices and systems. They may apply fluid mechanics to model and optimize the flow of blood, oxygen, and other fluids in the body, making this course a possible fit.
Materials Scientist
Materials Scientist
Materials Scientists research and develop new materials, such as polymers, metals, and ceramics. They may use fluid mechanics to study the flow of fluids through materials, making this course a potential fit.
For more career information including salaries, visit:
OpenCourser.com/course/uri3s9/exploring
Reading list
We've selected 11 books
that we think will supplement your
learning. Use these to
develop background knowledge, enrich your coursework, and gain a
deeper understanding of the topics covered in
Exploring fluid mechanics using Wolfram notebook.
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Comprehensive and up-to-date textbook on fluid mechanics. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners.
Comprehensive and up-to-date textbook on viscous fluid flows. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners.
Classic textbook on boundary layer theory. It provides a comprehensive overview of the subject, from basic principles to advanced applications. It valuable resource for both students and practitioners.
Save
Comprehensive and up-to-date textbook on incompressible flow. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners.
Comprehensive and up-to-date textbook on turbulence. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners.
Provides a comprehensive overview of geophysical fluid dynamics. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners who are interested in understanding the fluid dynamics of the Earth's oceans and atmosphere.
Provides a comprehensive overview of computational fluid mechanics. It covers a wide range of topics, from basic concepts to advanced applications. It valuable resource for students and practitioners who are interested in using computational methods to solve fluid mechanics problems.
Comprehensive and up-to-date textbook on computational fluid dynamics. It covers a wide range of topics, from basic concepts to advanced applications. It valuable resource for students and practitioners who are interested in using computational methods to solve fluid mechanics problems.
Provides a comprehensive overview of the fluid mechanics of environmental interfaces. It covers a wide range of topics, from basic principles to advanced applications. It valuable resource for both students and practitioners who are interested in understanding the fluid dynamics of the Earth's oceans, atmosphere, and land surface.
Save
Well-written and accessible introduction to fluid mechanics. It covers a wide range of topics, from basic concepts to advanced applications. It good choice for students who are new to the subject.
Well-written and accessible introduction to fluid mechanics. It covers a wide range of topics, from basic concepts to advanced applications. It good choice for students who are new to the subject.
For more information about how these books relate to this course, visit:
OpenCourser.com/course/uri3s9/exploring
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Effort
2 hours
Level
Intermediate
Via
Coursera
Institution
Coursera Project Network
Instructor
Ashish Dikshit
Language
English
Good to know
Explores fluid mechanics, which is vital for understanding fluids in various industries such as engineering, physics, and aerospace
Taught by Ashish Dikshit, who is highly recognized for his expertise and research in fluid mechanics
Involves hands-on computations and simulations, enhancing practical understanding of fluid mechanics principles
Develops proficiency in fluid mechanics, which is essential for solving real-world engineering problems involving fluids
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